KR101563509B1 - measuring device of sunlight quantity - Google Patents

Abstract

The present invention relates to a solar photovoltaic apparatus, and more particularly, to a solar photovoltaic apparatus including a case having a housing space formed therein, a substrate provided on one side of the housing space, and a plurality of photosensors arranged on the substrate, An optical sensor array unit and an alignment error calculation unit for analyzing the detection signals of the optical sensors and calculating a solar alignment error.
According to the present invention as described above, slits having different heights of the tubular shape are provided on top of a plurality of photosensors, and the change of the light amount of sunlight sensed by each photosensor according to the change of the incident angle of the sunlight is finely measured So that it is possible to more accurately measure the vertical position of the sunlight.
In addition, when a plurality of optical sensors are calibrated, a plurality of optical sensors can be calibrated by one inspection light, thereby minimizing the occurrence of errors due to calibration.
In addition, a temperature stabilizing unit that can maintain the ambient temperature of the optical sensor constant can be provided, and more accurate light amount can be measured through the optical sensor.
In addition, by coating the light absorbing material on the inner wall of the case and the slit, it is possible to prevent an error caused by reflection or scattering of incident sunlight, and to measure a more accurate amount of light.

Description

Measuring device of sunlight quantity

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar photometric apparatus, and more particularly, to a solar photovoltaic apparatus capable of accurately measuring the position of sunlight by comparing light quantities measured by a plurality of optical sensors provided with slits having tube- ≪ / RTI >

In order to use and enjoy the civilization of modern society, most of them have to borrow the power of electricity. Most of the electric energy relies on the fossil energy, that is, the coal-fired power plant that burns coal and oil to turn the steam turbine and obtain energy.

However, fossil energy has been limited in its reserves, and environmental pollution and global warming due to carbon dioxide generated when burning it have always been a problem.

Therefore, solar energy has attracted attention as an alternative energy for such fossil energy. In order to convert solar energy into electric energy, a conversion device such as a solar panel is required. The solar panel uses a property that an electromotive force is generated inside a semiconductor junction region having a PN junction surface when light is irradiated, And became popular as an energy source.

In order to maximize the utilization efficiency of the solar energy, the solar panel must be rotated so that the sun can always be viewed vertically. For this purpose, Korean Patent No. 1122617 discloses a structure in which a central light hole is formed on one side, And a central light transmission line communicating with the central light transmission hole are vertically penetrated through the upper and lower portions, and four outer light transmission lines communicating with the outer transmission light holes are vertically penetrated through the upper and lower portions, respectively, And a central light receiving sensor provided on a lower portion of the body and opposed to a lower end of the central light transmission line, wherein the central light receiving sensor is provided at a lower portion of the body, And four outer light receiving sensors provided opposite to the lower end of the outer transparent line The sensor assembly including the plate is installed in parallel with the solar panel so that the amount of light sensed by the two outer light receiving sensors in the east-west direction and the north-south direction are compared and the light amounts of the two outer light receiving sensors are compared with each other, And a driving motor is driven to rotate the solar panel so that the solar panel is kept in a state always perpendicular to the sunlight.

However, the light-receiving sensor for measuring the amount of sunlight has a characteristic that the performance varies depending on the change of the surrounding environment. In particular, due to the characteristic change depending on the temperature change around the device, A characteristic compensation circuit with a temperature sensor is used. However, since the temperature sensor is also influenced by the external temperature, it is difficult to secure a stable and accurate value.

In addition, each light receiving sensor installed in the sensor assembly may cause an error according to the installation environment and aging, so that the calibration process is required after installation of the product. However, the above- Since the line is formed to be inclined, it is necessary to inspect the respective inspection light beams for calibration of each outer light receiving sensor in the calibration process without individually irradiating them to each of the outer light receiving sensors, and there is a possibility that an error may occur in the calibration process. There is a problem that calibration can not be performed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a photovoltaic apparatus capable of finely measuring the amount of incident light of sunlight by providing slits having different tube shapes at the top of a plurality of optical sensors, .

It is another object of the present invention to provide a solar photovoltaic apparatus having a temperature stabilizing portion inside a case so that the ambient temperature of the light sensor can be kept constant.

Another object of the present invention is to provide a photovoltaic element measuring apparatus in which a light absorbing material is coated on an inner wall of a case and a slit to prevent incident sunlight from being reflected or scattered.

According to an aspect of the present invention, there is provided a light emitting device including a case having a housing space formed therein, a substrate provided on one side of the housing space, and a plurality of photosensors arranged on the substrate, And an alignment error calculation unit for calculating a solar alignment error by analyzing detection signals of the photosensor array unit and each of the photosensors.

The plurality of optical sensors include a reference optical sensor disposed at the center and a peripheral optical sensor disposed outside the reference optical sensor, wherein the slit includes a reference optical sensor slit provided in the reference optical sensor, And the reference optical sensor slit is formed to have the highest height.

Also, the plurality of the ambient light sensors are arranged in a cross shape around the reference light sensor for two-dimensional solar light alignment detection, and installed in pairs of ambient light sensors arranged opposite to each other with reference to the reference light sensor It is more preferable that the ambient light sensor slits are formed at different heights.

It is further preferable that a light absorbing material is coated on the side wall of the case and the inner surface of the slit.

In addition, it is preferable that a temperature stabilizing part for maintaining the internal temperature of the case at a predetermined temperature is further formed.

The temperature stabilizer may include a temperature sensor installed at one side of the substrate, a thermoelectric element provided at a lower portion of the substrate, and a temperature controller for comparing the temperature value detected from the temperature sensor with a predetermined temperature value to drive the thermoelectric element .

According to the present invention as described above, slits having different heights of the tubular shape are provided on top of a plurality of photosensors, and the change of the light amount of sunlight sensed by each photosensor according to the change of the incident angle of the sunlight is finely measured So that it is possible to more accurately measure the vertical position of the sunlight.

In addition, when a plurality of optical sensors are calibrated, a plurality of optical sensors can be calibrated by one inspection light, thereby minimizing the occurrence of errors due to calibration.

In addition, a temperature stabilizing unit that can maintain the ambient temperature of the optical sensor constant can be provided, and more accurate light amount can be measured through the optical sensor.

In addition, by coating the light absorbing material on the inner wall of the case and the slit, it is possible to prevent an error caused by reflection or scattering of incident sunlight, and to measure a more accurate amount of light.

1 is a perspective view of a solar photovoltaic apparatus according to the present invention.
2 is a sectional view of a solar photovoltaic apparatus according to the present invention.
3A is a schematic view showing a state in which sunlight inclines incident on the solar light amount measuring apparatus according to the present invention.
FIG. 3B is a schematic view illustrating a state in which sunlight is vertically incident on the solar light amount measuring apparatus according to the present invention.
FIG. 4 is a schematic view showing a process of calibrating an optical sensor of a solar photovoltaic apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. It is to be noted that like elements in the drawings are represented by the same reference numerals as possible. In the following description, well-known functions or constructions that may unnecessarily obscure the gist of the invention will not be described in detail.

FIG. 1 is a perspective view of a solar photovoltaic apparatus according to the present invention, and FIG. 2 is a sectional view of a solar photovoltaic apparatus according to the present invention.

1 and 2, a solar photovoltaic apparatus 1 according to the present invention includes a case 10, an optical sensor array unit 20, an alignment error calculation unit 30, and a temperature stabilization unit 40 .

The case 10 is formed in a hexahedron shape and has an accommodation space formed therein to provide an installation area of the optical sensor array unit 20, the alignment error calculation unit 30, and the temperature stabilization unit 40, which will be described later.

The case 10 is preferably made of a transparent material so that sunlight can be incident on the inside of the case 10, and a light absorbing material is preferably coated on the inner surface of the side wall to prevent incident sunlight from being reflected or scattered.

As described above, the light absorbing material is coated on the inner surface of the side wall of the case 10 to prevent incident sunlight from being reflected or scattered and incident on the optical sensor array unit 20 described later, .

The optical sensor array unit 20 includes a substrate 21 and a plurality of optical sensors 22 and 24 provided with tube-shaped slits 23 and 25 on the top.

The substrate 21 is provided on one side of the inner space of the case 10 to provide an installation area of the optical sensor.

 The plurality of optical sensors 22 and 24 are disposed on the upper surface of the substrate 21, and the slits provided in the respective optical sensors are formed at different heights.

The reason why the slits 23 and 25 having different heights are provided in the plurality of photosensors 22 and 24 as described above is that when the sunlight is incident obliquely, a difference in amount of light incident on each photosensor is generated, And to estimate the alignment error of the sunlight and the solar tracking device 50 by comparing the difference in the amount of light between the optical sensors.

The optical sensor array unit 20 includes a reference optical sensor 22 installed at the center of the substrate 21, a reference optical sensor slit 23 provided at an upper portion of the reference optical sensor 22, Four ambient light sensors 24 arranged in a cross shape around the reference light sensor 22 and four ambient light sensor slits 25 provided in the four ambient light sensors 24.

Here, it is preferable that the reference light sensor slit 23 provided in the reference light sensor 22 is formed at the highest level to minimize the amount of solar light incident on the reference light sensor 22 when the sunlight inclines. The amount of solar light incident on the reference light sensor 22 and the amount of solar light incident on the four ambient light sensors 24 are compared with each other to determine whether the solar light incident on the reference light sensor 22 and the four ambient light sensors 24 It becomes possible to more accurately measure the vertical position at which the light amount becomes equal.

The peripheral light sensor slits 25 provided in the two pairs of the ambient light sensors 24 arranged to face each other in the cross direction with respect to the reference light sensor 22 are formed at different heights, Dimensional direction with respect to the sunlight by comparing the amount of sunlight incident on the ambient light sensor 24 of the sunlight.

It is preferable that the light absorbing material is coated on the inner wall of the reference light sensor slit 23 and the inner light sensor slit 25 to prevent incident sunlight from being reflected or scattered.

As described above, the light absorbing material is coated on the inner wall of the reference light sensor slit 23 and the ambient light sensor slit 25 to reflect or scatter the incident sunlight and enter into the reference light sensor 22 and the ambient light sensor 24 It is possible to obtain a more accurate measurement value because the error generating factors are eliminated.

In the present embodiment, the reference light sensor slit 23 and the ambient light sensor slit 25 are expressed as a square tube shape, but the present invention is not limited thereto, and the light sensor slit 23 and the ambient light sensor slit 25 may be formed into a polygonal tube shape or a circular tube shape Of course.

The alignment error calculation unit 30 calculates the solar alignment error value by analyzing the amount of solar light detected from the reference light sensor 22 and the four ambient light sensors 24.

The solar tracking device 50 is driven in the direction in which the solar alignment error value calculated from the alignment error calculating unit 30 is erased as described above.

Here, the solar tracking device 50 may be a plant cultivation device or a solar photovoltaic device using solar light.

The alignment error calculation unit 30 may be configured to transmit the calculated solar alignment error value provided in the solar photometric apparatus 1 of the present invention to the solar tracking device 50, The apparatus 50 may be provided with an alignment error calculating section 30. [

The temperature stabilizing unit 40 is installed on one side of the housing space of the case 10 to maintain the ambient temperature of the reference light sensor 22 and the four ambient light sensors 24 at a predetermined temperature.

The temperature stabilizer 40 includes a temperature sensor 41 disposed on one side of the substrate 21 and a thermoelectric element 43 and a temperature controller 42 disposed below the substrate 21.

The temperature sensor 41 measures the temperatures of the reference light sensor 22 and the four ambient light sensors 24 provided on the upper surface of the substrate 21 and transmits the detected temperature value to the temperature controller 42 .

The thermoelectric element 43 serves to maintain the temperature inside the case 10 at a predetermined temperature.

The temperature control unit 42 serves to drive the thermoelectric element 43 by comparing the measured temperature value from the temperature sensor 41 with a preset temperature value.

As described above, by keeping the ambient temperature of the reference light sensor 22 and the four ambient light sensors 24 at a predetermined temperature through the temperature stabilizing unit 40, it is possible to minimize the influence of each ambient light temperature on each of the light sensors So that more accurate measurement can be performed.

FIG. 3A is a schematic view showing a state in which sunlight is inclinedly incident on the solar light amount measuring apparatus according to the present invention, FIG. 3B is a schematic view showing a state in which sunlight is incident vertically on the solar light amount measuring apparatus according to the present invention, Fig.

3A, when the solar light amount measuring device 1 of the present invention and the solar light amount measuring device 1 of the present invention are positioned at an incline in the initial operation of the solar light amount measuring device 1 according to the present invention, The ambient light sensor slit 23 provided in each pair of the ambient light sensors 24 arranged so as to be opposed to each other with reference to the reference light sensor 22 are formed at different heights A difference occurs in the amount of sunlight incident on the reference light sensor 22 and the pair of ambient light sensors 24.

At this time, after the solar tracking device 50 is driven in the direction of the four ambient light sensors 24, the amount of light incident on the reference light sensor 22 and each pair of ambient light sensors 24 at each position Are compared through the alignment error calculating unit 30.

Then, the solar tracking device 50 is driven in such a direction that the amounts of light incident on the reference light sensor 22 and the respective pairs of ambient light sensors 24 are approximately equal to each other, So that the measuring apparatus 1 is vertically positioned.

When the position of the sun moves finely in the process of driving the solar tracking device 50 such that the solar light measuring device 1 is perpendicular to the solar light measuring device 1, So that the sunlight and the sunlight measuring device 1 are positioned so as to be perpendicular to each other.

FIG. 4 is a schematic view showing a process of calibrating an optical sensor of a solar photovoltaic apparatus according to the present invention.

Referring to FIG. 4, the reference light sensor 22 and the four ambient light sensors 24 installed in the solar light amount measuring apparatus according to the present invention generate errors according to the installation environment and aging.

Therefore, in order to eliminate such an error, the inspection light 60 having the same light quantity is irradiated to each sensor, and the offset values are compared so that the respective output values outputted from the respective optical sensors are compared and equalized.

The apparatus for measuring the amount of sunlight according to the present invention includes a reference light sensor 22 and four reference light sensor slits 23 and ambient light sensor slits 25 provided on the four ambient light sensors 24, It is possible to simultaneously irradiate and illuminate the reference light sensor 22 and the plurality of ambient light sensors 24 with the inspection light 60 irradiated for correcting the respective light sensors, It is possible to measure a more accurate measurement value by preventing an error that may be caused by irradiating the inspection light 60 on the inspection light 60 individually.

Although the present invention has been described in connection with the preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. It is, therefore, to be understood that the appended claims will include all such modifications and changes as fall within the true spirit of the invention.

1: solar photometer 10: case
20: optical sensor array unit 21: substrate
22: reference light sensor 23: reference light sensor slit
24: ambient light sensor 25: ambient light sensor slit
30: Alignment error calculating unit 40: Temperature stabilizing unit
41: temperature sensor 42: temperature control unit
43: thermoelectric element 50: solar tracking device
60: inspection light

Claims (6)

A case having a housing space formed therein;
A photosensor array unit including a substrate disposed on one side of the accommodation space, and a plurality of photosensors arranged on an upper surface of the substrate, the plurality of photosensors having tube-shaped slits formed thereon; And
And an alignment error calculation unit for calculating a solar alignment error by analyzing the detection signals of the respective photosensors,
Wherein each of the slits provided in the plurality of optical sensors is formed to have a different height from each other, and is arranged perpendicular to the substrate.
The method according to claim 1,
The plurality of optical sensors
A reference optical sensor disposed centrally;
And a plurality of ambient light sensors disposed outside the reference light sensor,
Wherein the slit comprises a reference optical sensor slit provided on the reference optical sensor;
And a plurality of ambient light sensor slits respectively installed in the ambient light sensor of the cover,
And the height of the reference optical sensor slit is formed to be the highest.
3. The method of claim 2,
A plurality of the ambient light sensors are disposed in a cross shape around the reference light sensor for detecting solar light alignment in a two-dimensional direction, and the ambient light sensors disposed in pairs of the ambient light sensors disposed opposite to each other with respect to the reference light sensor Wherein the optical sensor slits are formed at different heights.
The method according to claim 1,
And a light absorbing material is coated on the side wall of the case and the inner surface of the slit.
The method according to claim 1,
And a temperature stabilizing unit for maintaining the temperature inside the case at a preset temperature.
6. The method of claim 5,
The temperature stabilizing unit
A temperature sensor installed on one side of the substrate;
A thermoelectric element provided below the substrate; And
And a temperature controller for comparing the temperature value detected by the temperature sensor with a preset temperature value to drive the thermoelectric element.

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